Transition Cow Nutrition: The Critical 6 Weeks from the Dry Period to Lactation | VetKriter

The transition period in dairy cattle covers the 3 weeks before calving and the 3 weeks after calving, and it is the most critical physiological window determining the course of the entire lactation. During this phase, negative energy balance (NEB), immunosuppression, and endocrine changes create the basis for metabolic and infectious disorders such as ketosis, hypocalcemia, metritis, displaced abomasum, and mastitis. This article reviews transition physiology, nutritional strategies, and metabolic disease prevention protocols in light of current literature.

Critical Statistic

In dairy cows, 75% of metabolic and infectious diseases occur during the first 3 weeks after calving. Nutritional errors made during the transition period can cause a 10-25% loss in milk yield across the entire lactation and a 15-20% increase in premature herd removal (Drackley, 1999; LeBlanc et al., 2006).

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1. Definition of the Transition Period and Physiological Foundations

The concept of the transition period was first defined systematically by Grummer (1995). It describes the stage during which the cow moves physiologically from the dry pregnant state into lactation and experiences its most intense endocrine, metabolic, and immunological adaptation.

Prepartum Period (−21 days)

Dry matter intake (DMI) declines by 30-35%
Fetal growth increases energy demand
Insulin resistance develops and NEFA mobilization begins
Immune function becomes suppressed as cortisol rises
Colostrum synthesis begins and Ca/Ig demand increases

Periparturient Period (±3 days)

DMI reaches its lowest point
Progesterone drops sharply while estrogen peaks
Cortisol and prostaglandins increase
Calcium demand increases 3-4 fold for colostrum
Oxidative stress reaches its peak

Postpartum Period (+21 days)

Milk yield rises rapidly and deepens the energy gap
DMI recovers slowly, peaking around weeks 10-14
NEB is most severe: −10 to −25 Mcal/day
Risk of fatty liver is highest
Uterine involution and reproductive recovery continue

1.1 Physiology of Negative Energy Balance (NEB)

After calving, milk production increases much faster than dry matter intake. This energy deficit is covered by mobilization of body fat reserves. Non-esterified fatty acids (NEFA) released from adipose tissue are transported to the liver, where they are metabolized through three major pathways (Drackley, 1999):

Hepatic NEFA Metabolism

1. Complete oxidation

β-oxidation → CO₂ + ATP
Energy production (ideal pathway)

2. Partial oxidation

β-oxidation → ketone bodies
(BHB, acetoacetate, acetone)
Ketosis risk

3. Re-esterification

NEFA → triglyceride (TG)
Hepatic lipidosis
Fatty liver syndrome

Clinical Threshold Values

NEFA (prepartum): ≥0.3 mEq/L increases metabolic disease risk by 2-4 times (Ospina et al., 2010)
NEFA (postpartum): ≥0.7 mEq/L is associated with a marked rise in clinical disease risk
BHB (β-hydroxybutyrate): ≥1.2 mmol/L indicates subclinical ketosis (McArt et al., 2012)
BHB: ≥3.0 mmol/L indicates clinical ketosis
Liver TG: >5% of wet weight suggests moderate to severe hepatic lipidosis

1.2 Endocrine Changes and Homeorhetic Adaptation

During the transition period, the endocrine system undergoes a homeorhetic adaptation to redirect nutrients toward milk synthesis. This concept was first defined by Bauman and Currie (1980).

Hormone	Change	Metabolic Effect	Clinical Outcome
Insulin	↓ Decreases	Peripheral glucose use declines and glucose is redirected to milk synthesis	Lipolysis increases and NEFA rises
Growth hormone (GH)	↑ Increases	Stimulates lipolysis and increases gluconeogenesis	Milk output rises and NEB deepens
IGF-1	↓ Decreases	GH-IGF-1 axis becomes uncoupled	Reproductive function is suppressed
Leptin	↓ Decreases	Feed intake regulation becomes impaired	Reduced appetite and BCS loss
Cortisol	↑ Increases	Raises gluconeogenesis and contributes to immunosuppression	Higher susceptibility to infection
Progesterone	↓↓ Sharp decline	Triggers parturition and initiates lactogenesis	Colostrum synthesis starts and Ca demand rises

2. Prepartum Feeding Strategies (−21 to 0 days)

2.1 Dry Matter Intake Management

Maintaining DMI during the prepartum period directly influences postpartum metabolic disease risk. Hayward et al. (2006) showed that every 1 kg decline in DMI during the last week before calving increases postpartum NEFA concentration by 0.08 mEq/L.

Prepartum DMI Targets (NASEM, 2021)

Parameter	Target	Explanation
DMI	1.8-2.0% of body weight	For a 650 kg cow: 11.7-13.0 kg DM/day
NEL	1.25-1.35 Mcal/kg DM	Excess energy raises postpartum disorder risk
CP	12-14% of DM	Metabolizable protein target: 1000-1100 g/day
NDF	33-40% of DM	Supports rumen fill and rumen health
NFC	32-38% of DM	Supports rumen papilla adaptation

2.2 Energy Feeding: The Controlled Energy Approach

Studies by Dann et al. (2006) and Janovick et al. (2011) demonstrated that excessive prepartum energy intake (>100% of requirement) suppresses postpartum DMI, raises NEFA and BHB concentrations, and worsens hepatic fat accumulation.

Controlled Energy Principle

During the prepartum period, energy intake should meet 100% of requirements but should not exceed 110%. This strategy:

Raises postpartum DMI by 8-12%
Reduces hepatic TG accumulation by 40-60%
Lowers subclinical ketosis incidence by 30-50%
Usually relies on straw or low-quality forage to limit ration energy density

2.3 DCAD (Dietary Cation-Anion Difference) Strategy

A negative DCAD diet during the prepartum period is the most effective nutritional strategy for preventing hypocalcemia. The DCAD formula is:

DCAD (mEq/kg DM) = (Na⁺ + K⁺) − (Cl⁻ + S²⁻)

Target DCAD: −10 to −15 mEq/100 g DM in the prepartum period

Negative DCAD creates a mild metabolic acidosis, improves parathyroid hormone receptor sensitivity, and facilitates calcium mobilization from bone (Goff, 2008).

DCAD Source	Application	Points of Attention
Anionic salts	MgCl₂, CaCl₂, MgSO₄, CaSO₄	Palatability may decline and reduce DMI
Commercial anionic products	Encapsulated anionic salt products	Palatability problems are partly reduced
Low-K forage sources	Wheat straw, corn silage	Alfalfa is usually high in K and should be limited

Urine pH Monitoring

The effectiveness of a negative DCAD program is monitored through urine pH measurement. Target urine pH is 6.0-6.5 in Holsteins and 5.8-6.2 in Jerseys. If pH is above 7.0, DCAD is not sufficiently negative; if pH is below 5.5, the risk of excessive acidosis rises. Measure 8-10 cows, two to three times per week, before the morning feeding (Goff, 2008).

2.4 Rumen Papilla Adaptation

In cows fed low-energy dry cow rations, rumen papillae may become atrophic. A sudden increase in concentrate feeding after calving can impair VFA absorption by the rumen epithelium and promote subacute ruminal acidosis (SARA) (Dieho et al., 2016).

Rumen Adaptation Protocol

3 weeks before calving: Begin gradual concentrate increases, usually about 0.5 kg per day
2 weeks before calving: Start introducing the grain sources used in the lactation ration
1 week before calving: Concentrates should reach 30-35% of dietary DM
Goal: Increase rumen papilla surface area by 50-70%; this adaptation typically requires 4-6 weeks

3. Postpartum Feeding Strategies (0 to +21 days)

3.1 Early Lactation Energy Management

During the first 3 weeks after calving, milk yield may rise by 1-2 kg per day while DMI increases by only 0.5-1.0 kg per day. This asymmetry creates a daily energy deficit of −10 to −25 Mcal. According to NRC (2001), a cow producing 35 kg of milk per day during the first week postpartum can meet only about 65-75% of her energy requirement.

Parameter	Early Lactation Target	Explanation
NEL density	1.65-1.75 Mcal/kg DM	High-producing cows may require up to 1.80 Mcal/kg DM
CP	16-18% of DM	Metabolizable protein target: 2200-2800 g/day depending on yield
RUP proportion	35-40% of CP	Bypass protein sources become especially important
NDF	28-32% of DM minimum	Effective NDF should remain around 21-22% of DM
NFC	36-42% of DM	Excess NFC increases SARA risk
Fat	5-7% of DM total	Protected fat is commonly fed at 200-500 g/day

3.2 Protected (Bypass) Nutrients

Protected Choline

Rumen-protected choline (RPC) facilitates VLDL synthesis and export from the liver, reducing triglyceride accumulation and helping prevent hepatic lipidosis.

Dose: 12-15 g/day of protected choline
Timing: From 21 days before calving to 21 days after calving
Effect: Liver TG decreases by 25-40% (Zom et al., 2011)

Protected Methionine

A critical amino acid for milk protein synthesis and antioxidant defense because it supports glutathione production.

Dose: Metabolizable methionine at 2.2-2.5% of MP
Timing: Prepartum and early lactation
Effect: Milk protein rises and oxidative stress declines (Osorio et al., 2014)

Protected Fat

Raises dietary energy density without disturbing rumen fermentation. Palmitic acid (C16:0) is especially associated with improved milk fat output.

Dose: 200-500 g/day
Type: Ca soaps, hydrogenated fats, and C16:0-rich supplements
Effect: NEL increases while metabolic heat load falls (Palmquist & Jenkins, 2017)

3.3 Propylene Glycol and Glucogenic Precursors

Propylene glycol (PG) is converted in the rumen to propionate and helps support hepatic gluconeogenesis, thereby lowering ketosis risk. McArt et al. (2011) showed that routine postpartum BHB screening combined with PG treatment of positive cows reduced subclinical ketosis incidence by 50%.

Propylene Glycol Protocol

Prophylactic use: 300 mL/day by oral drench from 10 days before calving to 10 days after calving
Therapeutic use: 500 mL/day by oral drench for 3-5 days in cows with BHB ≥1.2 mmol/L
Caution: Excessive dosing (>500 mL/day) can contribute to rumen acidosis

4. Mineral and Vitamin Management

4.1 Calcium Homeostasis

At calving, calcium demand rises 3-4 fold to support colostrum synthesis, moving from about 20-30 g/day to 50-80 g/day. This abrupt increase can reduce serum calcium concentration and lead to hypocalcemia. According to Reinhardt et al. (2011), 50% of multiparous cows experience subclinical hypocalcemia with serum Ca below 8.0 mg/dL.

Mineral	Prepartum	Postpartum	Critical Note
Calcium	0.40-0.50% of DM	0.80-1.00% of DM	Must be managed together with DCAD
Phosphorus	0.30-0.35% of DM	0.35-0.45% of DM	Maintain a Ca:P ratio of 1.5-2.0:1
Magnesium	0.35-0.45% of DM	0.30-0.40% of DM	Critical for parathyroid hormone function
Potassium	≤1.2% of DM	1.0-1.5% of DM	Should remain low prepartum for DCAD control
Sodium	0.10-0.12% of DM	0.30-0.50% of DM	Should remain low prepartum for DCAD control
Sulfur	0.30-0.40% of DM	0.20-0.25% of DM	Often used as an anionic salt source

4.2 Trace Minerals and Vitamins

Trace Minerals

Selenium: 0.3 mg/kg DM, preferably from organic sources. Supports lower mastitis and retained placenta incidence (Weiss, 2003)
Copper: 12-18 mg/kg DM for immune competence and antioxidant defense
Zinc: 55-75 mg/kg DM for hoof health and tissue repair
Manganese: 40-60 mg/kg DM for reproductive and bone metabolism
Organic trace minerals: Usually provide 15-30% higher bioavailability than inorganic forms

Vitamins

Vitamin E: 1000-3000 IU/day prepartum. Improves neutrophil function and lowers retained placenta and mastitis risk (LeBlanc et al., 2004)
Vitamin A: 75,000-100,000 IU/day for epithelial integrity and immunity
Vitamin D: 20,000-30,000 IU/day to support calcium absorption and bone metabolism
Niacin (B3): 6-12 g/day for energy metabolism and possible NEFA reduction, although evidence remains mixed
Biotin: 20 mg/day to support hoof quality and gluconeogenesis

5. Metabolic Disease Cascade During the Transition Period

Transition disorders do not usually occur in isolation. Instead, they develop as an interconnected cascade in which the presence of one disorder amplifies the risk of others (Mulligan & Doherty, 2008).

Metabolic Disease Cascade

Primary Problem	Secondary Risks	Increase in Risk
Subclinical hypocalcemia	Ketosis, metritis, displaced abomasum, mastitis	2-8 times depending on outcome
Subclinical ketosis	Displaced abomasum, metritis, mastitis, poorer fertility	Displaced abomasum: 8 times
Retained placenta	Metritis, endometritis, prolonged days open	Metritis: 3-5 times
Excessive BCS loss (>1 point)	Ketosis, fatty liver, immunosuppression	Ketosis: 3-4 times

Prevention Strategy: “Fresh Cow” Protocol

A practical monitoring routine for the first 10 days after calving:

Days 1-3: Rectal temperature, DMI observation, and colostrum quality in colostrum cows (Brix ≥22%)
Days 3-5: BHB testing in blood or milk and urine ketone checks
Days 5-7: Milk yield trend and vaginal discharge scoring
Days 7-10: BCS evaluation and rumination activity
If BHB ≥1.2 mmol/L: Propylene glycol 500 mL/day for 3-5 days
If rectal temperature ≥39.5°C: Evaluate for metritis

6. Body Condition Score (BCS) Management

During the transition period, BCS is one of the most reliable indicators of metabolic status. The meta-analysis by Roche et al. (2009) showed that the optimal BCS at calving is 3.0-3.25 on a 5-point scale.

BCS at Calving	Risk Profile	Expected Outcomes
≥3.75	Very high risk	Ketosis ×4, fatty liver ×5, displaced abomasum ×3
3.50	High risk	Ketosis ×2, marked decline in DMI
3.00-3.25	Optimal	Lowest disease risk and best milk production outcome
2.50-2.75	Lower metabolic risk / higher production risk	Reduced milk potential and inadequate energy reserves
≤2.25	Very high risk	Insufficient energy reserve, immunosuppression, low milk yield

Limits for BCS Loss

During the first 60 days after calving, BCS loss should not exceed 0.5-0.75 points. Every 0.5-point loss corresponds to approximately 56 kg of body fat mobilization. When BCS loss exceeds 1.0 point, ketosis risk rises by 3-4 times and the risk of impaired reproductive performance rises by 2-3 times (Roche et al., 2009).

7. Immune Function and the Transition Period

Immune function is physiologically suppressed during the transition period. This is linked to the prepartum cortisol rise, metabolic stress associated with NEB, and oxidative stress. Sordillo and Aitken (2009) showed that neutrophil chemotaxis and phagocytic capacity decrease by 25-40% around calving.

Causes of Immunosuppression

Cortisol: Suppresses lymphocyte proliferation and cytokine production
NEFA: Reduces neutrophil oxidative burst capacity
BHB: Inhibits leukocyte chemotaxis and phagocytosis
Hypocalcemia: Impairs smooth muscle contraction and slows uterine involution
Oxidative stress: Reactive oxygen species damage cells and immune competence

Immune Support Strategies

Vitamin E + Se: Improve antioxidant defense and neutrophil function
Protected methionine: Supports glutathione synthesis and antioxidant capacity
Organic trace minerals: Cu, Zn, and Mn support immune cell function
Omega-3 fatty acids: Potential anti-inflammatory benefit, though evidence is mixed
Minimizing NEB: Better energy balance helps preserve immune competence

8. Practical Transition Ration Examples

8.1 Prepartum Ration Example (650 kg Holstein, BCS 3.25)

Feed Ingredient	Amount (kg DM/day)	Proportion (% of DM)
Corn silage	4.0	33
Chopped wheat straw	3.0	25
Soybean meal (48% CP)	1.5	12
Ground corn	1.5	12
Anionic mineral premix	0.5	4
Protected choline	0.06	0.5
Vitamin-mineral premix	0.25	2
TOTAL	~12.0 kg DM

NEL: ~1.30 Mcal/kg DM | CP: ~13.5% | NDF: ~38% | DCAD: ~−12 mEq/100 g DM

8.2 Early Lactation Ration Example (650 kg Holstein, 35 kg milk/day)

Feed Ingredient	Amount (kg DM/day)	Proportion (% of DM)
Corn silage	7.0	30
Alfalfa hay	3.5	15
Ground corn	5.0	22
Soybean meal (48% CP)	3.0	13
Protected soy / bypass protein	1.0	4
Protected fat (calcium soap)	0.5	2
Sodium bicarbonate	0.20	0.9
Protected choline	0.06	0.3
Vitamin-mineral premix	0.30	1.3
TOTAL	~23.0 kg DM

NEL: ~1.72 Mcal/kg DM | CP: ~17% | RUP: ~38% of CP | NDF: ~30% | NFC: ~40%

9. Monitoring Parameters and Early Warning Indicators

Parameter	Measurement Method	Target Value	Alarm Threshold	Frequency
BHB (blood)	Portable ketone meter	<0.8 mmol/L	≥1.2 mmol/L	Every 2 days from 3 to 14 days after calving
NEFA (blood)	Laboratory analysis	<0.3 mEq/L (pre) / <0.7 mEq/L (post)	≥0.3 / ≥0.7 mEq/L	7-10 days before calving and 3-7 days after calving
Urine pH	pH paper or pH meter	6.0-6.5	>7.0 or <5.5	2-3 times weekly in herds using DCAD
Rectal temperature	Digital thermometer	38.5-39.0°C	≥39.5°C	Daily during the first 10 days postpartum
BCS	Visual scoring + palpation	3.0-3.25 at calving	Loss >0.75 points/60 days	At dry-off, calving, day 30, and day 60
Rumination	Observation or sensor	>450 min/day	<400 min/day	Continuous with sensors or observed daily
Milk yield	Milking system records	Consistent upward trend	Decline on 2 consecutive days	At every milking

10. Herd-Level Success Criteria for the Transition Period

Criterion	Target	Alarm Threshold
Subclinical ketosis prevalence	<15%	>25%
Clinical ketosis incidence	<5%	>8%
Clinical hypocalcemia	<3%	>5%
Displaced abomasum	<3%	>5%
Retained placenta	<8%	>12%
Metritis	<10%	>15%
Removal from the herd within 60 days	<5%	>8%
Time to peak milk yield	6-8 weeks after calving	>10 weeks

11. References

Bauman, D. E., & Currie, W. B. (1980). Partitioning of nutrients during pregnancy and lactation: A review of mechanisms involving homeostasis and homeorhesis. Journal of Dairy Science, 63(9), 1514-1529.
Dann, H. M., et al. (2006). Diets during far-off and close-up dry periods affect periparturient metabolism and lactation in multiparous cows. Journal of Dairy Science, 89(9), 3563-3577.
Dieho, K., et al. (2016). Effect of supplemental concentrate during the dry period or early lactation on rumen epithelium gene and protein expression in dairy cattle during the transition period. Journal of Dairy Science, 99(6), 4506-4519.
Drackley, J. K. (1999). Biology of dairy cows during the transition period: The final frontier? Journal of Dairy Science, 82(11), 2259-2273.
Goff, J. P. (2008). The monitoring, prevention, and treatment of milk fever and subclinical hypocalcemia in dairy cows. The Veterinary Journal, 176(1), 50-57.
Grummer, R. R. (1995). Impact of changes in organic nutrient metabolism on feeding the transition dairy cow. Journal of Animal Science, 73(9), 2820-2833.
Janovick, N. A., et al. (2011). Prepartum dietary energy intake affects metabolism and health during the periparturient period in primiparous and multiparous Holstein cows. Journal of Dairy Science, 94(3), 1385-1400.
LeBlanc, S. J., et al. (2004). Peripartum serum vitamin E, retinol, and beta-carotene in dairy cattle and their associations with disease. Journal of Dairy Science, 87(3), 609-619.
LeBlanc, S. J., et al. (2006). Major advances in disease prevention in dairy cattle. Journal of Dairy Science, 89(4), 1267-1279.
McArt, J. A. A., et al. (2011). A field trial on the effect of propylene glycol on milk yield and resolution of ketosis in fresh cows diagnosed with subclinical ketosis. Journal of Dairy Science, 94(12), 6011-6020.
McArt, J. A. A., et al. (2012). Epidemiology of subclinical ketosis in early lactation dairy cattle. Journal of Dairy Science, 95(9), 5056-5066.
Mulligan, F. J., & Doherty, M. L. (2008). Production diseases of the transition cow. The Veterinary Journal, 176(1), 3-9.
NASEM (National Academies of Sciences, Engineering, and Medicine). (2021). Nutrient Requirements of Dairy Cattle (8th rev. ed.). Washington, DC: The National Academies Press.
NRC (National Research Council). (2001). Nutrient Requirements of Dairy Cattle (7th rev. ed.). Washington, DC: National Academy Press.
Osorio, J. S., et al. (2014). Supplemental Smartamine M or MetaSmart during the transition period benefits postpartal cow performance. Journal of Dairy Science, 97(3), 1413-1423.
Ospina, P. A., et al. (2010). Evaluation of nonesterified fatty acids and β-hydroxybutyrate in transition dairy cattle in the northeastern United States: Critical thresholds for prediction of clinical diseases. Journal of Dairy Science, 93(2), 546-554.
Reinhardt, T. A., et al. (2011). Prevalence of subclinical hypocalcemia in dairy herds. The Veterinary Journal, 188(1), 122-124.
Roche, J. R., et al. (2009). Invited review: Body condition score and its association with dairy cow productivity, health, and welfare. Journal of Dairy Science, 92(12), 5769-5801.
Sordillo, L. M., & Aitken, S. L. (2009). Impact of oxidative stress on the health and immune function of dairy cattle. Veterinary Immunology and Immunopathology, 128(1-3), 104-109.
Weiss, W. P. (2003). Selenium nutrition of dairy cows: Comparing responses to organic and inorganic selenium forms. Proceedings of the 19th Alltech Annual Symposium, 333-343.
Zom, R. L. G., et al. (2011). Effect of rumen-protected choline on performance, blood metabolites, and hepatic triacylglycerols of periparturient dairy cattle. Journal of Dairy Science, 94(8), 4016-4027.